Manufacturing apparatus for the production of magnetized water and its method

ABSTRACT

The objective of the present invention is to provide both a device and a method therewith for efficient production of magnetized water useful in living body&#39;s metabolism by changing the arrangement of molecules of water, taking advantage of the phenomenon that molecules of water are disposed to form clusters and become enriched in a pulsating magnetic field. To achieve the objective, the device of the present invention comprises a chamber which is shaped like a vessel for a container of purified water to be laid in it and which is wound with coils of wire on its outer wall for a certain predetermined number of rounds; a means of supplying power to convert the originally supplied alternating current of electricity into pulsating direct current signals of a certain frequency and impress them on said coils for induction of a pulsating magnetic field to said chamber; a means of cooling, installed on the outer side of said chamber to cool the heat generated by said coils; a means of sensing the changes in the temperature generated by said coils; a means of measuring time to gauge the time of magnetization of said purified water; and a means of control to stop the inputting of direct current pulsating signals at the moment when, measured by said means of measuring time, the time spent on magnetizing has reached its preset time.

TECHNICAL FIELD

[0001] The present invention relates to a device and a method forproduction of magnetized water and, in particular, to a device and amethod for its production by making use of the phenomenon that moleculesof water form clusters and concentrate themselves in a field ofpulsating magnetism.

BACKGROUND ART

[0002] Magnetized water is by nature the more significant for showingthe characteristics of a peculiar water through change of thearrangement of its molecules under the influence of magnetism than thefact that its molecules gain a magnetic trait by magnetization, andthereupon various studies and researches have so far been made about thephysicochemical characteristics of magnetized water.

[0003] For example, it has been reported that when water is magnetizedand used in the industries the scale caused by water inside pipesdecreases and that if magnetized water is used in rinsing mouths fewerdental calculi result. For another example of biological reactions inliving bodies there has been a report that in magnetized water theactivity of glutamate decarboxylase is greater by some 30% than inordinary water, and so have there been many other reports on the virtuesof magnetized water.

[0004] In especial, many researches have been made of uses of moleculesof water in living bodies, and it is known that, in most processes ofmetabolism in a living body, such biochemical reactions as syntheses anddegradation of protein or nucleic acid as well as storage and release ofenergy take place through the reactions of molecules of water in theprocesses of their rearrangement. However, it is also known that suchbiochemical reactions of molecules of water do not take place bymolecules of water in direct reaction with other biological substancesbut some suitable solutes, which have functions as buffer, are necessaryfor them to take place. Water, a main solvent in a living body, has suchsolutes dissolved in it as Na⁺, Ka⁺, Ca⁺⁺, Mg⁺⁺, Zn⁺⁺,Fe−, PO4 ⁻, Cl⁻,etc., playing the role of a buffer by keeping the solvent's pH orosmotic pressure to a certain level.

[0005] What needs to notice here is that the above-listed solutes arecapable of reacting with molecules of water and change theirarrangement.

[0006] To explain in further detail, a sodium ion Na⁺ and a potassiumion Ka⁺ bring about in a living body quite opposite biochemicalreactions. On the one hand, the former, Na⁺, by a reaction withmolecules of water, assumes an arrangement, whereby it is encircled bythese molecules, resulting in dispersion of them to assemble arounditself, causing this way a swelling of the arrangement of molecules ofwater. Whereupon, water's osmotic pressure increases, and this way, too,weakening the dipolarity of water by forcefully attracting molecules ofwater, to be followed by decrease of water's reaction with othersolutes.

[0007] On the other hand, the latter, potassium ion, Ka⁺, assumes anarrangement in the form of encircling molecules of water, and thus, bygathering them close together group by group, forms clusters ofmolecules of water.

[0008] Lately, according to the results of the studies through No(nuclear magnetic resonance) of the clusters of molecules of waterexisting on the inner walls of endoplasmic reticulum or mitochondria inliving cells, it has been learned that, compared with the constituentsof the substrate of a cell, the clusters of molecules of water are ingreater concentration, and this can be explained by stating thatpotassium ions Ka⁺ concentrate the clusters of molecules of water andfacilitate the reaction of the resultant concentrated molecules of waterwith structures of endoplasmic reticulum or mitochondria within cells.Accordingly, it can also be said that a smooth intercellular metabolismtakes place through the phenomena of concentration of the clusters ofmolecules of water.

DISCLOSURE OF THE INVENTION

[0009] In the present invention, accordingly, it is intended to providea device and a method therewith for production of magnetized water goodfor the metabolism in a living body by changing the arrangement ofmolecules of water by a pulsating magnetic field, without the help ofany inorganic substances, but through formation thereby of the clustersof molecules of water, their concentration, and maintenance of theirmagnetic properties for a certain length of time.

BRIEF DESCRIPTION OF DRAWINGS

[0010]FIG. 1 is a drawing to illustrate the device for production ofmagnetized water in Embodiment Example 1 of the present invention.

[0011]FIG. 2 is a waveform diagram of the voltage on a first coil inEmbodiment Example 1.

[0012]FIG. 3 is a waveform diagram of the voltage induced on a secondcoil in Embodiment Example 1.

[0013]FIG. 4 is a drawing to illustrate the device for production ofmagnetized water in Embodiment Example 2.

[0014]FIG. 5 is a drawing to illustrate the device for production ofmagnetized water in Embodiment Example 3.

[0015]FIGS. 6 and 7 are the drawings for explanation of the magneticrelaxation time in the present invention.

[0016]FIG. 8 is a drawing for explanation of the time spent onmagnetization in the present invention.

[0017]FIGS. 9a through 9 f show the changes in the viscosity of water Ithe present invention.

[0018]FIGS. 10a and 10 b show the conductivity rates of the magnetizedwater in the present invention.

[0019]FIGS. 11a and 11 a show the solubility of the magnetized water inthe present invention.

[0020]FIG. 12 is a table to explain the oxygen solubility of themagnetized water in the present invention.

[0021]FIG. 13 is a table to explain the free radical activity of themagnetized water in the present invention.

BEST MODE FOR CARRYING OUT THE INVENTION

[0022] To attain the above-said objective, the device for production ofmagnetized water of the present invention is characterized in that itcomprises a chamber, which houses a vessel containing purified water init, and the outer wall of which is wound with a coils of wire by acertain number of rounds; a means of supplying power, which convertsalternating current into a series of pulsating direct current signalswith a preset frequency to impress said coils in order to generate apulsating magnetic field inside said chamber; a means of cooling placedoutside said chamber to cool the heat caused by said coils; a means ofsensing temperature to detect changes of the temperature caused by saidcoils; a means of measuring time to measure the time of magnetization ofsaid purified water; and a means of control, which compares the timespent on the actual magnetization with the preset time for it and hassaid power supply means break off the impression of said pulsating DCsignals directly the preset time is reached.

[0023] The device is also characterized in that, besides theabove-listed basic constituents, it further comprises a water tankwhich, placed outside said chamber but connected with it, which receivesthe supply of water from an outside source; and that the water in saidtank is magnetized in said chamber and thereafter the magnetized wateris circulated to said tank, said tank having a means of outlet, too, todischarge the magnetized water outside with ease.

[0024] The method for production of magnetized water in the presentinvention is characterized in that a magnetism having a certainintensity and pulsating with a preset frequency is impressed on thewater purified and contained in a tightly closed vessel, the impressionwith said magnetism is continued so long as the spin arrangement of themolecules of water keeps unchanged, and this way the molecules of waterare made to form clusters, whereby enriched magnetized water isobtained.

[0025] Below, the invention is described in further detail, the attacheddrawings being referred to each time.

[0026]FIG. 1 being a drawing for description of the device forproduction of magnetized water in Embodiment Example 1 of the presentinvention, said device is constructed, as is shown in the drawing, of achamber 4, which houses a vessel to contain purified water inside andwhich is wound with coils of wire by a certain number of rounds; a powersupply section 6, which converts the alternating current (AC) ofelectricity into pulsating direct current (C) signals for impression onsaid coils in order to induce a magnetic field to the inside of saidchamber 4; a cooling section 8, placed outside said chamber 4 to coolthe heat caused by said coils; a temperature sensing section 10 todetect changes of the temperature caused by said coils; a time measuringsection 12 to measure the time spent on magnetization of the purifiedwater, and a control section 14 to control said power supply section 6in accordance with the temperature detected by said temperature sensingsection 10 and the time of magnetization measured by said time measuringsection 12.

[0027] It is preferable to place a counter-electromotive force cutoffcircuit 16 between said coils and power supply section 6, whereby toblock intrusion of counter-electromotive force which is given rise to bysaid coils and shield said power supply section 6 from it.

[0028] Of coils, in order to minimize the magnetic field offset effectswhich are to be occasioned at the central part of said coils by theinfluence of the polarity a second coil 2 is connected in series, at aninterval P. with a first coil 1, which receives said pulsating DCsignals from said power supply section 6.

[0029] The first coil 1 and said second coil 2 are enwrapped with ashielding screen to block off the counter-electromotive force which isgiven rise to when the pulsating magnetic filed is induced

[0030] The chamber 4 will be of a vertical structure large enough tohouse a vessel of the size of 1-liter PET bottle, and it will be formedof nonferrous metals to be capable of inducing magnetism of a properintensity.

[0031] The power supply section 6 is so constructed as to convert thealternating current into a direct current of 16˜24V for supply for theperipheral devices, e.g., said cooling section 8, generate a sufficientpulsating magnetic field in a short time, and convert said alternatingcurrent into DC signals pulsating at 3˜7 Hz per second to input them tosaid first coil 1 lest the counter-electromotive force which isgenerated inside the coils should offset said generated magnetic field,while it is preferable to provide both the inputting and outputtingterminals with a double flise device for the sake of an operator'ssafety.

[0032] The cooling section 8 is placed outside said chamber 4,comprising an air-cooling pan and a circulatory air-passage (not shownin the drawings).

[0033] The operation of the device in Embodiment Example 1, constructedas above, is described below.

[0034] After a tightly closed vessel containing purified ortwice-filtered water is placed in said chamber 4, power is turned on,and a power supply section 6 converts the alternating current ACsupplied under the control of said control section 14 into DC pulsatingat 3˜7 Hz per second to input them to said first coil 1.

[0035] When said pulsating DC signals are impressed on said first Coil1, a magnetic field with an intensity to satisfy the range of 600˜1,000gauss and pulsation in the range of 3˜7 Hz is generated inside saidchamber 4 by virtue of the intermission of said pulsating DC signals. Atthis time the waveform of the voltage of the pulsating DC signalsimpressed on said first coil 1 is as shown in FIG. 2, that on a secondcoil 2 being as shown in FIG. 3.

[0036] When such a pulsating magnetic field as induced the way describedabove is generated in repetition for a given length of time, thearrangement of the molecules of the purified water contained in saidvessel inside said chamber 4 sharply changes as time passes, but at acertain time this change slows down and reaches the stage of saturation.At this time the molecules of water form clusters and a phenomenon ofcondensation occurs. Now the time for the arrangement of the moleculesof water to reach saturation is termed the magnetization time.

[0037] Such a phenomenon is distinct in that the spin arrangement ofhydrogen atoms persists, from the phenomenon of magnetic resonance, inwhich the hydrogen atoms undergo a spin arrangement under strongmagnetism for an instant but immediately to return to their originalstate. In this case the hydrogen atoms exert an influence on thehydrogen ions peculiar to the dipolarity of the molecules of water andthereby the distances between the hydrogen atoms gradually decrease.This can be seen from the analysis of the NMR (nuclear magneticresonance) by the fact that the magnetic relaxation time, i.e., the timefor the molecules of water to return to their original state by theirrearrangement, increases. In the air, the molecular arrangement ofmagnetized water returns almost to its original state in about 24 hours.

[0038] The magnetization time in the present invention, it has beenlearned through experiments, is preferably to be set at 6˜24 hours.

[0039] The magnetization time is set at said control section 14 inadvance and said control section 14 observes to see whether the timemeasured at said time measuring section 12 is past the preset time formagnetization.

[0040] If, as a result of this observation the measured time is over thepreset time, said control section 14 controls said first coil 1 to stopimpression of said DC pulsating signals on said first coil 1.

[0041] When magnetization of water is performed by impression ofpulsating DC signals on said coils this way, heat is generated in saidfirst and second coils 1, 2 which raises the temperature inside saidchamber 4, and if the temperature inside said chamber 4 goes beyond acertain degree, e.g., 30° C., said temperature sensing section 10 sendsoff a warning signal.

[0042] In response to said signals from said temperature sensing section10 said control section 14 so controls said power supply section 6 thatthe latter will impress a driving signal to said cooling section 8. Thisway the temperature inside said chamber 4 is maintained consistently ata desired level.

[0043] Next, FIG. 4 is an illustration to describe the device forproduction of magnetized water according to Embodiment Example 2 of thepresent invention, and the device is in the basic idea the same as thatof Embodiment Example 1.

[0044] The device in this example is the same as Example 1 in that itcomprises a chamber which houses a vessel containing purified water andwhich is wound with coils on its outside by a certain number of rounds;a shielding screen to cover said coils; a power supply section whichconverts the originally alternating current of electricity intopulsating DC signals and impresses them on said coils to induce amagnetic field to the inside of said chamber; a temperature sensingsection to detect the changes of temperature caused by said coils; atime measuring section to measure the magnetization time of saidpurified water; and a control section, which so controls said powersupply section to impress pulsating DC signals on said coils accordingto the temperature sensed by said temperature sensing section and thetime measured by said time measuring section. Accordingly, superfluousrepetitive detailed descriptions are omitted, while as to the sameconstituents the same numbers or symbols are used for the sake ofconvenience.

[0045] The main characteristics of the device in this example lie inthat a way of cooling by compression of refrigerant by evaporation isadopted, instead of the aircooling method in Example 1. That is, acooling pipe 20 serving as a vaporizer is set in the form of a screwbetween said chamber 4 and a coil 3, and this cooling pipe 20 isconnected by a connection pipe 28 with a compressor 22 and a condenser24, whereby the refrigerant issuing from said cooling pipe 20 can beresupplied to said cooling pipe 28 through said compressor 22 and saidcondenser 24 to augment the cooling, resulting in a more efficientcooling than otherwise of the heat of coils and maintain the temperatureof the magnetized water in the vessel in said chamber 4 at its properlevel (4° C.˜8° C.).

[0046] In order further to improve the cooling efficiency, a cooling pan26′, 26″ is placed on the outside respectively of said coil 3 woundround said chamber 4 and said condenser 24 in an ordinary way, whereby,in addition to said cooling by compression by vaporization of saidrefrigerant, a secondary cooling can be performed by these cooling pans.In this example it is not necessary to divide said coil 3 in two, as wasdine in Example 1, because the cooling is thus much more efficient inthis example.

[0047] Further, to house all these additional constituents, a case 30 isformed, which has a partitioning board 36 inside it, the spaces aboveand below said partitioning board 36 are respectively made into amagnetizing chamber 32 and a cooling chamber 34. Here in saidmagnetizing chamber 32 a chamber 4 wound with said coil 3 and saidcooling 20 pipe as well as said cooling pan 26′ are placed, while insaid cooling chamber said compressor 22, said condenser 24, and saidcooling pan 26″ are placed on the floor.

[0048] The upper part of said case 30, that is, said magnetizing chamber32, is cut out to provide an opening as large as the diameter of saidchamber 47 just enough to bring in and out said vessel of water, whilesaid opening has to have a lid capable of opening or closing at will forthe purpose of protection of the magnetizing space and of prevention ofaccidents which might possibly be caused by inadvertency of an operatorat work.

[0049] The partitioning board 36 preferably has a number of holes forexhaust of heat and drainage of water, and said magnetizing chamber 32and said cooling chamber 34 have to be of a structure good for smoothcirculation of air.

[0050] For efficient operation and its easy observation said controlsection 14 is placed at a proper position in the front or a side of saidcase 30, and said control section 14 (See FIG. 1) is of an ordinarystructure of a panel (not shown in the drawings).

[0051] On the bottom of said case 30 three or more castors are fittedfor its easy movement about.

[0052] The operation of the device in Embodiment Example 2 of thepresent invention is basically the same as that of the device in Example1, except that said coil for impression of the pulsating DC signals fromsaid power supply section 6 (See FIG. 1) is single and not plural innumber, wherefore its detailed description is omitted here.

[0053]FIG. 5 is for illustration of Embodiment Example 3 of the presentinvention, in which the device for production of magnetized wateraccording to Embodiment Example 2 above is in use in the home oroffices; where, the basic idea of production of magnetized water is thesame as that in the cases of the devices in Examples 1 and 2. The samenumbers and symbols as used in these earlier examples are therefore inuse in the descriptions of this example also.

[0054] The device in this example is characterized, however, by aspecific construction, in which it has inside said magnetizing chamber32 a water tank 18, separate from said chamber 4 for production ofmagnetized water, whereby the water in said tank 18 is magnetized insaid chamber 4, restored in said tank 18, and made available outsidethrough an ordinary faucet 38.

[0055] Below, the device in Embodiment Example 3 is described in furtherdetail.

[0056] In the upper part of said case 30, which is divided into saidmagnetizing chamber 32 above and said cooling chamber 34 below, viz., inthe upper part of said magnetizing chamber 32 is placed a water tank 18,for storage of water, which is connected with said chamber 4 by aconnection pipe 28′ joined to its upper and lower parts. On saidconnection pipe 28′, which connects said chamber 4 and said water tank18, is placed a circulatory pump 40, which is not merely for drawing thewater from said water tank 18 but also for sending it back aftermagnetization for storage in said water tank 18. If not shown in FIG. 5,it is so structured that said water tank 18 is automatically suppliedwith water from an outside source, and that this supply will have to bemechanically controlled through a constant measurement of the water insaid tank 18 in order that it may always keep a certain quantity ofwater or magnetized water stored in it.

[0057] At one side on the bottom of said water tank 18, a drain pipe 28″is connected for discharge of the magnetized water through said faucet38, and said drain pipe 28 has a cooling pipe 20 attached to it forcooling the water being drained.

[0058] On said chamber 4 in this example, too, a coil and shieldingscreen are set, as were in Example 2 above, while a power supplysection, a control section, a time measuring section, a temperaturesensing section, a counter-electromotive force cut-off circuit, etc. arealso placed, whose construction and operation are omitted fromdescription here as they are the same as in Embodiment Examples 1 and 2.

[0059] Meanwhile, though FIG. 5 shows the arrangement of a compressor, acondenser, a cooling pan, etc., inside said cooling chamber 34 formed inthe lower part of said case 30, as in Embodiment Example 2, it is alsopreferable to have a cooling pan inside the aforesaid magnetizingchamber, too.

[0060] Moreover, it is preferable in this example also to have castors(not shown in the drawings) under said case 30 for a smooth movement ofthis particular item of equipment, while said control section,preferably structured in a panel, can be attached to the front or on aside of said case 30 to secure a handy operation of the device and itsquick observation.

[0061] Now the operation of the device in Embodiment Example 3 isbasically the same as that of the device in Examples 1 and 2.

[0062] Only, in this example, said water tank 18 is provided separatelyfrom said chamber 4 to receive-supply of water from an outside sourceand also restore the water after its magnetization in said chamber 4.Here, said circulatory pump which circulates the magnetized water iscontrolled by said control section 14 (See FIG. 1) in reference to themagnetization time, the quantity of used water, and other conditions. Inthe case where much water is in use, the magnetization time is shortenedand the operation cycle of said circulatory pump is lessened, to keepsaid water tank always full of magnetized water.

[0063] Therefore, according to the device for production of magnetizedwater in this example it is made possible for all times for peoplereadily to drink magnetized water through said faucet 38, as it is inthe case of the water purifier to serve both cold and hot drinking waterin the home or offices.

[0064] The physicochemical properties of the magnetized water producedby the device of the present invention are described below on the basesof its experiments. The magnetized water used in the experiments was thewater produced of deionized distilled water sealed in an airtight glassbottle inside said chamber (in Embodiment Examples 1 and 2 of thepresent invention).

[0065] First, to speak of the magnetic relaxation time, a phenomenon ofits increase was observed through NMR analysis, when irradiation with amagnetism pulsating at 7 Hz and with an intensity of 600˜1,000 gausscontinued for 24 hours, while the temperature of said chamber 4 was keptat 30° C.

[0066] As seen in FIG. 6, the magnetic relaxation time showed a sharpincrease for the first five hours and a mild rise after eight hours toreach its highest at the 12th hour since the irradiation had started,but thereafter the rise became sluggish and continued so until the24^(th) hour. The thus increasing magnetic relaxation began decreasefinally to stop exponentially and functionally, as shown in FIG. 7, asthe irradiation was discontinued. The decrease was sudden and sharp forthe first five hours after discontinuation of the irradiation, andcontinued its sluggish decrease for the hours until the 24^(th).

[0067] In FIGS. 6 and 7, the vertical and lateral axes respectively showthe time required for magnetization of deionized distilled water and thetime T corresponding with the time for the changes of the gaps betweenthe hydrogen atom pairs in the molecules of deionized water. Here, thetime T serves as indices to the magnetic relaxation times.

[0068] Meanwhile, as shown in FIG. 8, the magnetic relaxation time forthe magnetized deionized distilled water was greatly increased to2,453.3±3.21 from the 2,261.7±4.56 for ordinary deionized distilledwater, while it increased just a little bit to 2,243±1.31 when themagnetized deionized distilled water had 1.0% potassium chloride (KCl)dissolved in it by contrast with the 2,118±7.61 for ordinary deionizeddistilled water with 0.5% sodium chloride (NaCl) dissolved in it.

[0069] As for viscosity of the magnetized water, the deionized distilledwater magnetized for 24 hours showed, as in FIG. 9a, a very rapidincrease in viscosity in the initial period of time, compared withordinary deionized distilled water, but the thus quickly increasedviscosity got decreased to the level of the latter at about the 12^(th)hour.

[0070] A change of viscosity like this in water became distinct whensodium chloride (NaCl) and potassium chloride (KCl) were each added tothe water, as shown in FIGS. 9b through 9 f.

[0071] As seen in FIGS. 9b through 9 f, ordinary deionized distilledwater first showed a decrease in viscosity as the added sodium chloride(NaCl) was increased by 0.1M, 0.2M, but later came to normal, while, inthe case of the magnetized deionized distilled water, it showed adecrease in viscosity in the earlier stage when the sodium chloride(NaCl) was added by 0.1M only but showed almost no phenomenon of itsdecrease in the initial period when the sodium chloride (NaCl) was addedby 0.2M and 0.4M.

[0072] Yet, as shown in FIGS. 9d through 9 f, a phenomenon of initialincrease in viscosity was prominent when, to the magnetized deionizeddistilled water, potassium chloride (KCl) was added by 0.1M, 0.2M, and0.4M, and this increase in viscosity was especially prominent when theaddition was by 0.1M to continue until about 2,000 minutes, after which,characteristically, it started quickly to return to the level ofordinary deionized distilled water; when potassium chloride (KCl) wasadded by 0.2M in dissolution the initial increase in viscosity persisteduntil 4,000 minutes, and when the addition was raised to 0.4M theinitial increase persisted until 6,000 minutes.

[0073] As for conductivity, it was seen that in the cases of both themagnetized water and ordinary deionized distilled water conductivityconsiderably decreased, while in the cases of the water purified ofordinary fresh water and the tap water the decrease in conductivity wasless. When sodium chloride and potassium chloride were added by 0.01% indissolution, however, the conductivity instantly increased, as shown inFIGS. 10a and 10 b, and the duration of the increased conductivity wasslightly the more in the case of potassium chloride added than of sodiumchloride. This phenomenon is interpreted to mean that, in the case ofordinary water, NaCl or KCl is ionized and quickly rearranged along withthe molecules of water, while in the case of magnetized water sodium ion(Na⁺) or potassium ion (K⁺) instantly separates to deter the rise ofconductivity, because the molecules of water are in close arrangement byvirtue of its strong hydrogen bonding.

[0074] Next, as to the maximum solubility speed, when that of each NaCland KCl in water was measured by the use of Sephadex G-50 column inorder to see the reaction speed of the solvent and solute, the maximumsolution speed of NaCl was, as shown in FIG. 11a, remarkably decreasedin the case of the magnetized deionized distilled water than in the caseof ordinary deionized distilled water, the latter being shown in a dotline; the difference in maximum solution speeds of ordinary deionizeddistilled water and magnetized water became smaller finally to come toalmost equal as the condensation of NaCl approached its saturation.Meanwhile, the maximum solution speed of KCl increased in the magnetizeddeionized distilled water slightly more than in ordinary deionizeddistilled water, as is indicated by a dot line in FIG. 11b, but thedifference disappeared as the condensation of KCl increased to approachits saturation.

[0075] Again, as to the pattern of crystal formation in gypsum, NaCl,and KCl, it was learned that the structural composition was denser andmore compact when gypsum was hardened by the use of the magnetizeddeionized distilled water than of ordinary deionized distilled water,and the larger crystal construction was obtained the faster in theformer than in the latter case. When NaCl or KCl was added by 1% and 5%,the magnetized deionized distilled water formed by far the denser,larger crystal constructions than did ordinary deionized distilledwater.

[0076] Then, as to the magnetized water's oxygen solubility, as seen inFIG. 12, it decreased the more as magnetization went on in the case ofthe magnetized deionized distilled water than in the case of ordinarydeionized distilled water. In especial, from the vessel where themagnetization took place in a tight closure quite a quantity of gaseoussubstance was observed escaping. When natural fresh water wasmagnetized, too, the hydrogen solubility decreased.

[0077] In FIG. 12, the number 1 in the lateral axis indicates the caseof ordinary water, 2 of ordinary water exposed to atmosphere for sixhours, 3 of ordinary water exposed for 12 hours, 4 of the deionizeddistilled water magnetized for six hours, and 5 of the same, magnetizedfor 12 hours, while the numbers in the vertical axis shows the oxygensolubility.

[0078] As to free radical activity of the magnetized water, as shown inFIG. 13, the coloring reaction by p-nitro-phenylacetate was the less inthe case of the magnetized water than in the comparable ordinarydeionized distilled water, and the difference became bigger asmagnetization proceeded.

[0079] In FIG. 13, the number 1 in the lateral axis indicates the caseof ordinary deionized distilled water, 2 of the same water magnetizedfor six hours, 3 of the same magnetized for three hours, 4 of tap water,and 5 of natural fresh water, while the numbers in the vertical axisindicate the optical density, OD.

[0080] Finally, as to the polymerase chain reaction (PCR) and theenzymatic reaction of restriction endonuclease by the use of themagnetized water, it was learned that the production of DNA increased inthe PCR which used the magnetized water, compared with where thecomparable ordinary deionized distilled water was used. When Taq(thermos aquaticus) was gradually decreased, too, the PCR productsslightly increased where the magnetized water was used, compared withwhere the comparable ordinary deionized distilled water was used, andwhen template DNA was gradually decreased a phenomenal increase of PCRproducts was confirmed in the case of the magnetized water than in theother.

[0081] Meanwhile, in the enzymatic reaction activity of restrictionendonuclease, too, it was observed greater in the case of the magnetizedwater than in the comparable ordinary deionized distilled water.

[0082] Industrial Applicability

[0083] As has been described above, when the device for magnetizingwater and the method therefor are applied, it is possible to rearrangethe molecules of water by the use of a pulsating magnetic field, evenwithout the aid of other inorganic salts, and this way it is possible tofacilitate formation of clusters of water molecules for its enrichmentand, moreover, to maintain such characteristic properties of themagnetized water for some time (6˜24 hours), which invariably helpsobtainment of magnetized water, which does not merely activate provisionof nutrients demanded by living bodies but stimulates their metabolismalso.

What is claimed is:
 1. A device for producing magnetized water, whichcomprises: (a) a chamber, which houses a vessel containing purifiedwater and whose outer wall is wound with coils of wire by a certainnumber of rounds; (b) a means of supplying power, which convertsalternating current of electricity into pulsating direct current signalsand impresses said signals on said coils; (c) a means of coolinginstalled outside said chamber; (d) a means of sensing the changes oftemperature generated by said coils; (e) a means of measuring the timespent on magnetization of said purified water; and, (f) a means ofcontrolling said means of supplying power to stop impression of said DCpulsating signals when the magnetization time measured by said means ofmeasuring the time exceeds the preset magnetization time.
 2. The devicefor producing magnetized water according to claim 1, wherein said coilswound onto said chamber comprises a first coil which receives impressionof said DC pulsating signals from said means of supplying power, and asecond coil which is connected with said first coil at a certaininterval.
 3. The device for producing magnetized water according toclaim 2, wherein said first and second coils are so adjusted in theirnumbers of rounds as against said DC pulsating signals that magnetism ofintensity to satisfy the range of 600 to 1,000 gauss and pulsating atthree to seven Hz per second can be induced.
 4. The device for producingmagnetized water according to claim 3, wherein said first and secondcoils are enwrapped with a shield screen to cut off harmfulelectromagnetism which can be generated while said pulsating magnetismis induced.
 5. The device for producing magnetized water according toclaim 1, wherein said means of cooling comprises a cooling pipe windingin the form of a screw between said chamber and coils, and a connectingpipe so connected that refrigerant of said cooling pipe can circulatethrough a compressor, and a condenser, and back to said cooling pipe. 6.The device for producing magnetized water according to claim 5, whereina partition board is laterally placed inside a case which houses thedevice for producing magnetized water so that in the upper space abovesaid partition board said chamber wound with said coils and said coolingpipe are placed and in the lower space below said partition board saidcompressor and said condenser are placed.
 7. The device for producingmagnetized water according to claim 6, wherein in the upper part of saidcase an opening of the size of the diameter of said chamber is formed,and a lid is set so that said opening can be opened or closed.
 8. Adevice for producing magnetized water, which comprises: (a) a water tankcontaining purified water; (b) a chamber, which is connected to saidwater tank and whose outer wall is wound with coils by a certain numberof rounds; (c) a circulatory pump which circulates water through saidwater tank and said chamber; (d) a means of supplying power whichconverts alternating current of electricity into DC pulsating signals ofcertain frequency and impresses them on said coils; (e) a means ofcooling installed outside said chamber; (f) a means of sensing thechanges of temperature generated by said coils; (g) a means of measuringthe time spent on magnetizing said purified water; (h) a means ofcontrolling said means of supplying power to stop impression of said DCpulsating signals when the magnetization time measured by said means ofmeasuring the time exceeds the preset magnetization time; and, (i) ameans of discharging water in said water to the outside.
 9. The devicefor producing magnetized water according to claim 8, wherein said meansof cooling comprises a cooling pipe wound round said means ofdischarging, and a connecting pipe so connected that refrigerant of saidcooling pipe can circulate through a compressor, and a condenser, andback to said cooling pipe.
 10. The device for producing magnetized wateraccording to claim 9, wherein a partition board is laterally placedinside a case which houses the device for producing magnetized water sothat in the upper space above said partition board said chamber woundwith said coils and said cooling pipe are placed and in the lower spacebelow said partition board said compressor and said condenser areplaced.
 11. The device for producing magnetized water according to claim6 or claim 10, wherein a cooling pan is placed outside said condenserand said chamber.
 12. The device for producing magnetized wateraccording to claim 11, wherein said partition board has a number ofholes dug in it.
 13. The device for producing magnetized water accordingto any one of claims 1 through 10, wherein said coils and said means ofsupplying power respectively have a counter-electromotive force cut-offcircuit formed to cut off the counter-electromotive force caused by saidcoils.
 14. The device for producing magnetized water according to anyone of claims 1 through 10, wherein said means of supplying powerconverts alternating current of is electricity into DC pulsating signalspulsating at three through seven Hz per second and outputs the same. 15.The device for producing magnetized water according to claim 14, whereinsaid chamber is made of nonferrous metal materials.
 16. A method forproducing magnetized water, which comprises impressing pulsatingmagnetism of a certain intensity and frequency onto purified watercontained in a tightly closed vessel, and continuing said impression sofar as the spin alignment of molecules of water can persist with almostno change, thus making said water molecules to form clusters, andthereby obtaining enriched magnetized water.
 17. The method forproducing magnetized water according to claim 16, wherein said purifiedwater receives impression of said pulsating magnetism in the range of 6to 24 hours.
 18. The method for producing magnetized water according toclaim 16 or claim 17, wherein said pulsating magnetism is in the rangeof 600 through 1,000 gauss in intensity.
 19. The method for producingmagnetized water according to claim 18, wherein said pulsating magnetismis in the range of frequency of three to seven Hz per second.